features high current carrying capability high surge current capability types up to 1200v v rrm stud cathode and stud anode version standard jedec types diffused junction case style do-205ac (do-30) i f(av) 130 a @ t c 125 c i f(rms) 200 a i fsm @ 50hz 2000 a @ 60hz 2100 a i 2 t@ 50hz 20 ka 2 s @ 60hz 18 ka 2 s v rrm range 400 to 1200 v t j -40 to 180 c parameters 130hf(r) units major ratings and characteristics typical applications battery chargers converters power supplies machine tool controls 130hf(r) series stud version standard recovery diodes 130 a bulletin i2019/a
130hf(r) series voltage v rrm , maximum repetitive v rsm , maximum non- i rrm max. type number code peak reverse voltage repetitive peak rev. voltage @ 180c vvma 40 400 500 130hf(r) 80 800 900 15 120 1200 1300 electrical specifications voltage ratings i f(av) max. average forward current 130 a 180 conduction, half sine wave @ case temperature 125 c i f(rms) max. rms forward current 200 a dc @ 115c case temperature i fsm max. peak, one-cycle forward, 2000 t = 10ms no voltage non-repetitive surge current 2100 t = 8.3ms reapplied 1680 t = 10ms 100% v rrm 1760 t = 8.3ms reapplied sinusoidal half wave, i 2 t maximum i 2 t for fusing 20 t = 10ms no voltage initial t j = t j max 18 t = 8.3ms reapplied 14 t = 10ms 100% v rrm 13 t = 8.3ms reapplied i 2 ? t maximum i 2 ? t for fusing 200 ka 2 ? s t = 0.1 to 10ms, no voltage reapplied v f(to)1 low level value of threshold voltage v f(to)2 high level value of threshold voltage r f1 low level value of forward slope resistance r f2 high level value of forward slope resistance v fm max. forward voltage drop 1.5 v i pk = 500a, t j = 25 c parameter 130hf(r) u nits conditions forward conduction 0.76 (16.7% x p x i f(av) < i < p x i f(av) ), t j = t j max. 0.95 (i > p x i f(av) ), t j = t j max. 1.41 (16.7% x p x i f(av) < i < p x i f(av) ), t j = t j max. 1.02 (i > p x i f(av) ), t j = t j max. ka 2 s a v m w
d-5 130hf(r) series parameter 130hf(r) units conditions c t j max. operating temperature range -40 to 180 t stg max. storage temperature range -55 to 180 r thjc max. thermal resistance, junction to case 0.3 dc operation r thcs max. thermal resistance, case to heatsink 0.08 mounting surface, smooth, flat and greased t max. allowed mounting torque +0 -20% 11 not lubricated threads 10 lubricated threads wt approximate weight 120 g case style do-205ac(do-30) see outline table k/w nm thermal and mechanical specification d r thjc conduction (the following table shows the increment of thermal resistence r thjc when devices operate at different conduction angles than dc) 180 0.052 0.042 t j = t j max. 120 0.064 0.070 90 0.083 0.090 k/w 60 0.117 0.120 30 0.177 0.180 conduction angle sinusoidal conduction rectangular conduction units conditions ordering information table 130 hf r 120 p b v 1 23 4 5 6 device code 1 - essential part number 2 - diode 3 - none = stud normal polarity (cathode to stud) r = stud reverse polarity (anode to stud) 4 - voltage code: code x 10 = v rrm (see voltage ratings table) 5 - p = stud base do-205ac(do-30) 1/2" 20unf-2a m= stud base do-205ac(do-30) m12x1.75 6 - b = flag top terminals (for cathode/ anode leads) s = isolated lead with silicone sleeve (red = reverse polarity; blue = normal polarity) none = not isolated lead 7 - v = glass-metal seal 7
130hf(r) series outline table do-205ac (do-30) flag all dimensions in millimeters (inches) glass-metal seal max. 21 (0.82) max. 16.5 (0.65) 6.5 (0.26) min. dia. 8.5 (0.33) nom. 157 (6.18) 55 (2.16) min. dia. 23.5 (0.93) max. 24 (0.94) max. sw 27 * for metric device: m12 x 1.75 170 (6.69) 1/2"-20unf-2a* 12.5 (0.49) max. c.s. 16mm 2.6 (0.10) max. 2 35 (1.38) max. (0.015 s.i.) max. glass-metal seal max. 21 (0.82) max. dia. 23.5 (0.93) max. 24 (0.94) 12.5 (0.49) 16.5 (0.65) 5.6 (0.22) dia. 5.54 (0.22) 2.4 (0. 09) 27 (1.06) 41 (1.61) max. 9.5 (0.37) *for metric device. m12 x 1.75 36.5 (1.44) 1/2"-20unf-2a* conforms to jedec do-205ac (do-30) all dimensions in millimeters (inches)
d-7 130hf(r) series 110 120 130 140 150 160 170 180 0 20 40 60 80 100 120 140 30 60 90 120 180 average forward current (a) conduction angle 130hf(r) serie s r (dc) = 0.3 k/ w maximum allowable case temperature (c) thjc 110 120 130 140 150 160 170 180 0 40 80 120 160 200 240 dc 30 60 90 120 180 conduction period 130hf(r) series r (dc) = 0.3 k/ w thjc maximum allowable case temperature (c) average forward current (a) fig. 1 - current ratings characteristics fig. 2 - current ratings characteristics 0 20 40 60 80 100 120 140 160 180 maximum allowable ambient temperature (c) r = 0 . 1 k / w - d e l t a r t h s a 0 . 2 k / w 0 . 3 k / w 0 . 4 k / w 0 . 5 k / w 0 . 6 k / w 0 . 8 k / w 1 k / w 1 . 2 k / w 0 20 40 60 80 100 120 140 160 180 0 20 40 60 80 100 120 140 180 120 90 60 30 rm s li m i t conduction angle maximum average forward power loss (w) average forward current (a) 130hf(r) series t = 180c j 0 20 40 60 80 100 120 140 160 180 maximum allowable ambient temperature (c) r = 0 . 1 k / w - d e l t a r t h s a 0 . 2 k / w 0 . 3 k / w 0 . 4 k / w 0 . 6 k / w 0 . 8 k / w 1 k / w 1 . 2 k / w 0 .5 k/ w 0 40 80 120 160 200 240 0 40 80 120 160 200 240 dc 180 120 90 60 30 rm s li m i t conduction period maximum average forward power loss (w) average forward current (a) 130hf(r) series t = 180c j fig. 3 - forward power loss characteristics fig. 4 - forward power loss characteristics
130hf(r) series 400 600 800 1000 1200 1400 1600 1800 110100 number of equa l amplitude half cycle current pulses (n) peak half sine wave forward current (a) init ia l t = 180 c @ 60 hz 0.0083 s @ 50 hz 0.0100 s j 130hf(r) series at any rated load condition and with rated v applied following surge. rrm 400 600 800 1000 1200 1400 1600 1800 2000 0.01 0.1 1 pulse train duration (s) peak half sine wave forward current (a) init ia l t = 180 c no voltage reapplied rated v reapplied rrm maximum non repetitive surge current j 130hf(r) s eries versus pulse train duration. fig. 5 - maximum non-repetitive surge current fig. 6 - maximum non-repetitive surge current 10 100 1000 10000 012345 t = 25c j instantaneous forward voltage (v) instantaneous forward current (a) 130hf(r) se rie s t = 180c j fig. 7 - forward voltage drop characteristics fig. 8 - thermal impedance z thjc characteristics 0.01 0.1 1 0.001 0.01 0.1 1 10 square wave pulse durat ion (s) thjc transient thermal impedance z (k/w) steady state value: r = 0.3 k/ w (dc operation) t hjc 130hf( r) se rie s
|
